Methods and systems for determining reservoir properties of subterranean formations

ABSTRACT

Methods and systems are provided for evaluating subsurface earth oil and gas formations. More particularly, methods and systems are provided for determining reservoir properties such as reservoir transmissibilities and average reservoir pressures of a formation layer or multiple layers using fracture-injection/falloff test methods. The methods herein may use pressure falloff data generated by the introduction of an injection fluid at a pressure above the formation fracture pressure in conjunction with a fracture-injection/falloff test model to analyze reservoir properties. The fracture-injection/falloff test model recognizes that a new induced fracture creates additional storage volume in the formation and that a fracture-injection/falloff test in a layer may exhibit variable storage during the pressure falloff, and a change in storage may be observed at hydraulic fracture closure.

CROSS-REFERENCE TO RELATED APPLICATION

The present invention is related to co-pending U.S. application Ser. No. ______ [Attorney Docket No. HES 2005-IP-018456U1] entitled “Methods and Systems for Determining Reservoir Properties of Subterranean Formations with Pre-existing Fractures,” filed concurrently herewith, the entire disclosure of which is incorporated herein by reference.

BACKGROUND

The present invention relates to the field of oil and gas subsurface earth formation evaluation techniques and more particularly, to methods and systems for determining reservoir properties of subterranean formations using fracture-injection/falloff test methods.

Oil and gas hydrocarbons may occupy pore spaces in subterranean formations such as, for example, in sandstone earth formations. The pore spaces are often interconnected and have a certain permeability, which is a measure of the ability of the rock to transmit fluid flow. Evaluating the reservoir properties of a subterranean formation is desirable to determine whether a stimulation treatment is warranted and/or what type of stimulation treatment is warranted. For example, estimating the transmissibility of a layer or multiple layers in a subterranean formation can provide valuable information as to whether a subterranean layer or layers are desirable candidates for a fracturing treatment. Additionally, it may be desirable to establish a baseline of reservoir properties of the subterranean formation to which comparisons may be later made. In this way, later measurements during the life of the wellbore of reservoir properties such as transmissibility or stimulation effectiveness may be compared to initial baseline measurements.

Choosing a good candidate for stimulation may result in success, while choosing a poor candidate may result in economic failure. To select the best candidate for stimulation or restimulation, there are many parameters to be considered. Some important parameters for hydraulic fracturing include formation permeability, in-situ stress distribution, reservoir fluid viscosity, skin factor, transmissibility, and reservoir pressure.

Many conventional methods exist to evaluate reservoir properties of a subterranean formation, but as will be shown, these conventional methods have a variety of shortcomings, including a lack of desired accuracy and/or an inefficiency of the method resulting in methods that may be too time consuming.

Conventional pressure-transient testing, which includes drawdown, buildup, or injection/falloff tests, are common methods of evaluating reservoir properties prior to a stimulation treatment. However, the methods require long test times for accuracy. For example, reservoir properties interpreted from a conventional pressure buildup test typically require a lengthy drawdown period followed by a buildup period of a equal or longer duration with the total test time for a single layer extending for several days. Additionally, a conventional pressure-transient test in a low-permeability formation may require a small fracture or breakdown treatment prior to the test to insure good communication between the wellbore and formation. Consequently, in a wellbore containing multiple productive layers, weeks to months of isolated-layer testing can be required to evaluate all layers. For many wells, especially for wells with low permeability formations, the potential return does not justify this type of investment.

Another formation evalution method uses nitrogen slug tests as a prefracture diagnostic test in low permeability reservoirs as disclosed by Jochen, J. E. et al., Quantifying Layered Reservoir Properties With a Novel Permeability Test, SPE 25864 (1993). This method describes a nitrogen injection test as a short small volume injection of nitrogen at a pressure less than the fracture initiation and propagation pressure followed by an extended pressure falloff period. The nitrogen slug test is analyzed using slug-test type curves and by history matching the injection and falloff pressure with a finite-difference reservoir simulator.

Conventional fracture-injection/falloff analysis techniques—before-closure pressure-transient as disclosed by Mayerhofer and Economides, Permeability Estimation From Fracture Calibration Treatments, SPE 26039 (1993), and after-closure analysis as disclosed by Gu, H. et al., Formation Permeability Determination Using Inpulse-Fracture Injection, SPE 25425 (1993)—allow only specific and small portions of the pressure decline during a fracture-injection/falloff sequence to be quantitatively analyzed. Before-closure data, which can extend from a few seconds to several hours, can be analyzed for permeability and fracture-face resistance, and after-closure data can be analyzed for reservoir transmissibility and average reservoir pressure provided pseudoradial flow is observed. In low permeability reservoirs, however, or when a relatively long fracture is created during an injection, an extended shut-in period—hours or possibly days—are typically required to observe pseudoradial flow. A quantitative transmissibility estimate from the after-closure pre-pseudoradial pressure falloff data, which represents the vast majority of the recorded pressure decline, is not possible with existing limiting-case theoretical models, because existing limiting-case models apply to only the before-closure falloff and the after-closure pressure falloff that includes the pseudoradial flow regime.

Thus, conventional methods to evaluate formation properties suffer from a variety of disadvantages including the lack of the ability to quantitatively determine the reservoir transmissibility, a lack of cost-effectiveness, computational inefficiency, and/or a lack of accuracy. Even among methods developed to quantitatively determine reservoir transmissibility, such methods may be impractical for evaluating formations having multiple layers such as, for example, low permeability stacked, lenticular reservoirs.

SUMMARY

The present invention relates to the field of oil and gas subsurface earth formation evaluation techniques and more particularly, to methods and systems for determining reservoir properties of subterranean formations using fracture-injection/falloff test methods.

An example of a method of determining a reservoir transmissibility of at least one layer of a subterranean formation having a reservoir fluid comprises the steps of: (a) isolating the at least one layer of the subterranean formation to be tested; (b) introducing an injection fluid into the at least one layer of the subterranean formation at an injection pressure exceeding the subterranean formation fracture pressure for an injection period; (c) shutting in the wellbore for a shut-in period; (d) measuring pressure falloff data from the subterranean formation during the injection period and during a subsequent shut-in period; and (e) determining quantitatively the reservoir transmissibility of the at least one layer of the subterranean formation by analyzing the pressure falloff data with a fracture-injection/falloff test model.

An example of a system for determining a reservoir transmissibility of at least one layer of a subterranean formation by using variable-rate pressure falloff data from the at least one layer of the subterranean formation measured during an injection period and during a subsequent shut-in period comprises: a plurality of pressure sensors for measuring pressure falloff data; and a processor operable to transform the pressure falloff data to obtain equivalent constant-rate pressures and to determine quantitatively the reservoir transmissibility of the at least one layer of the subterranean formation by analyzing the variable-rate pressure falloff data using type-curve analysis according to a fracture-injection/falloff test model.

An example of a computer program, stored on a tangible storage medium, for analyzing at least one downhole property comprises executable instructions that cause a computer to determine quantitatively a reservoir transmissibility of the at least one layer of the subterranean formation by analyzing the variable-rate pressure falloff data with a fracture-injection/falloff test model.

The features and advantages of the present invention will be apparent to those skilled in the art. While numerous changes may be made by those skilled in the art, such changes are within the spirit of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

These drawings illustrate certain aspects of some of the embodiments of the present invention and should not be used to limit or define the invention.

FIG. 1 is a flow chart illustrating one embodiment of a method for quantitatively determining a reservoir transmissibility.

FIG. 2 is a flow chart illustrating one embodiment of a method for quantitatively determining a reservoir transmissibility.

FIG. 3 is a flow chart illustrating one embodiment of a method for quantitatively determining a reservoir transmissibility.

FIG. 4 shows a graph of dimensionless pressure and pressure derivative versus dimensionless time and illustrates a case that exhibits constant before-closure storage, C_(bcD)=10, and constant after-closure storage, C_(acD)=1, with variable dimensionless closure time.

FIG. 5 presents a log-log graph of dimensionless pressure and pressure derivative versus dimensionless time without fracture-face skin, S_(fs)=0, but with variable choked-fracture skin, (S_(fs))_(ch)={0.05, 1, 5}.

FIG. 6 shows an example fracture-injection/falloff test without a pre-existing hydraulic fracture.

FIG. 7 shows an example type-curve match for a fracture-injection/falloff test without a pre-existing hydraulic fracture.

DESCRIPTION OF PREFERRED EMBODIMENTS

The present invention relates to the field of oil and gas subsurface earth formation evaluation techniques and more particularly, to methods and systems for determining reservoir properties of subterranean formations using fracture-injection/falloff test methods.

Methods of the present invention may be useful for estimating formation properties through the use of fracture-injection/falloff methods, which may inject fluids at pressures exceeding the formation fracture initiation and propagation pressure. In particular, the methods herein may be used to estimate formation properties such as, for example, the reservoir transmissibility and the average reservoir pressure. From the estimated formation properties, the methods of the present invention may be suitable for, among other things, evaluating a formation as a candidate for initial fracturing treatments and/or establishing a baseline of reservoir properties to which comparisons may later be made.

In certain embodiments, a method of determining a reservoir transmissibility of at least one layer of a subterranean formation having a reservoir fluid comprises the steps of: (a) isolating the at least one layer of the subterranean formation to be tested; (b)introducing an injection fluid into the at least one layer of the subterranean formation at an injection pressure exceeding the subterranean formation fracture pressure for an injection period; (c) shutting in the wellbore for a shut-in period; (d) measuring pressure falloff data from the subterranean formation during the injection period and during a subsequent shut-in period; and (e) determining quantitatively a reservoir transmissibility of the at least one layer of the subterranean formation by analyzing the pressure falloff data with a fracture-injection/falloff test model.

The term, “Fracture-Injection/Falloff Test Model,” as used herein refers to the computational estimates used to estimate reservoir properties and/or the transmissibility of a formation layer or multiple layers. The methods and theoretical model on which the computational estimates are based are shown below in Sections II and III. This test recognizes that a new induced fracture creates additional storage volume in the formation. Consequently, a fracture-injection/falloff test in a layer may exhibit variable storage during the pressure falloff, and a change in storage may be observed at hydraulic fracture closure. In essence, the test induces a fracture to rapidly determine certain reservoir properties.

More particularly, the methods herein may use an injection of a liquid or a gas in a time frame that is short relative to the reservoir response, which allows a fracture-injection/falloff test to be analyzed by transforming the variable-rate pressure falloff data to equivalent constant-rate pressures and plotting on constant-rate log-log type curves. Type curve analysis allows flow regimes—storage, pseudolinear flow, pseudoradial flow—to be identified graphically, and the analysis permits type-curve matching to determine a reservoir transmissibility. Consequently, substantially all of the pressure falloff data that may measured—from before-closure through after-closure—during a fracture-injection/falloff test may be used to estimate formation properties such as reservoir transmissibility.

The methods and models herein are extensions of and based, in part, on the teachings of Craig, D. P., Analytical Modeling of a Fracture-Injection/Falloff Sequence and the Development of a Refracture-Candidate Diagnostic Test, PhD dissertation, Texas A&M Univ., College Station, Tex. (2005), which is incorporated by reference herein in full and U.S. patent application Ser. No. 10/813,698, filed Mar. 3, 2004, entitled “Methods and Apparatus for Detecting Fracture with Significant Residual Width from Previous Treatments., which is incorporated by reference herein in full.

FIG. 1 shows an example of an implementation of the fracture-injection/falloff test method implementing certain aspects of the fracture-injection/falloff model. Method 100 generally begins at step 105 for determining a reservoir transmissibility of at least one layer of a subterranean formation. At least one layer of the subterranean formation is isolated in step 110. During the layer isolation step, each subterranean layer is preferably individually isolated one at a time for testing by the methods of the present invention. Multiple layers may be tested at the same time, but this grouping of layers may introduce additional computational uncertainty into the transmissibility estimates.

An injection fluid is introduced into the at least one layer of the subterranean formation at an injection pressure exceeding the formation fracture pressure for an injection period (step 120). In certain embodiments, the introduction of the injection fluid is limited to a relatively short period of time as compared to the reservoir response time which for particular formations may range from a few seconds to about 10 minutes. In preferred embodiments, the introduction of the injection fluid may be limited to less than about 5 minutes. In certain embodiments, the injection time may be limited to a few minutes. After introduction of the injection fluid, the well bore may be shut-in for a period of time from about a few hours to a few days, which in some embodiments may depend on the length of time for the pressure falloff data to show a pressure falloff approaching the reservoir pressure (step 130).

Pressure falloff data is measured from the subterranean formation during the injection period and during a subsequent shut-in period (step 140). The pressure falloff data may be measured by a pressure sensor or a plurality of pressure sensors. The pressure falloff data may then be analyzed according to step 150 to determine a reservoir transmissibility of the subterranean formation according to the fracture-injection/falloff model as shown below in more detail in Sections II and III. Method 200 ends at step 225.

FIG. 2 shows an example implementation of determining quantitatively a reservoir transmissibility (depicted in step 150 of Method 100). In particular, method 200 begins at step 205. Step 210 includes the step of transforming the variable-rate pressure falloff data to equivalent constant-rate pressures and using type curve analysis to match the equivalent constant-rate rate pressures to a type curve. Step 220 includes the step of determining quantitatively a reservoir transmissibility of the at least one layer of the subterranean formation by analyzing the equivalent constant-rate pressures with a fracture-injection/falloff test model. Method 200 ends at step 225.

FIG. 3 shows an example implementation of determining a reservoir transmissibility. Method 300 begins at step 305. Measured pressure falloff data is transformed to obtain equivalent constant-rate pressures (step 310). A log-log graph is prepared of the equivalent constant-rate pressures versus time (step 320). If pseudoradial flow has not been observed, type curve analysis may be used to determine quantitatively a reservoir transmissibility according to the fracture-injection/falloff test model (step 342). If pseudoradial flow has been observed, after-closure analysis may be used to determine quantitatively a reservoir transmissibility (step 346). These general steps are explained in more detail below in Sections II and III. Method 300 ends at step 350.

One or more methods of the present invention may be implemented via an information handling system. For purposes of this disclosure, an information handling system may include any instrumentality or aggregate of instrumentalities operable to compute, classify, process, transmit, receive, retrieve, originate, switch, store, display, manifest, detect, record, reproduce, handle, or utilize any form of information, intelligence, or data for business, scientific, control, or other purposes. For example, an information handling system may be a personal computer, a network storage device, or any other suitable device and may vary in size, shape, performance, functionality, and price. The information handling system may include random access memory (RAM), one or more processing resources such as a central processing unit (CPU or processor) or hardware or software control logic, ROM, and/or other types of nonvolatile memory. Additional components of the information handling system may include one or more disk drives, one or more network ports for communication with external devices as well as various input and output (I/O) devices, such as a keyboard, a mouse, and a video display. The information handling system may also include one or more buses operable to transmit communications between the various hardware components.

I. Analysis and Interpretation of Data Generally

A qualitative interpretation may use the following steps in certain embodiments:

-   -   Identify hydraulic fracture closure during the pressure falloff         using methods such as, for example, those disclosed in         Craig, D. P. et al., Permeability, Pore Pressure, and         Leakoff-Type Distributions in Rocky Mountain Basins, SPE         PRODUCTION & FACILITIES, 48 (February 2005).     -   The time at the end of pumping, t_(ne), becomes the reference         time zero, Δt=0. Calculate the shut-in time relative to the end         of pumping as         Δt=t−t _(ne)   (1)     -   In some cases, t_(ne), is very small relative to t and Δt=t. As         a person of ordinary skill in the art with the benefit of this         disclosure will appreciate, t_(ne) may be taken as zero         approximately zero so as to approximate Δt. Thus, the term Δt as         used herein includes implementations where t_(ne) is assumed to         be zero or approximately zero. For a slightly-compressible fluid         injection in a reservoir containing a compressible fluid, or a         compressible fluid injection in a reservoir containing a         compressible fluid, use the compressible reservoir fluid         properties and calculate adjusted time as $\begin{matrix}         {{t_{a} = {\left( {\mu\quad c_{t}} \right)_{p_{0}}{\int_{0}^{\Delta\quad t}\frac{{\mathbb{d}\Delta}\quad t}{\left( {\mu\quad c_{t}} \right)_{w}}}}}\quad} & (2)         \end{matrix}$     -   where pseudotime is defined as $\begin{matrix}         {{t_{p} = {\int_{0}^{t}\frac{\mathbb{d}t}{\left( {\mu\quad c_{t}} \right)_{w}}}}\quad} & (3)         \end{matrix}$     -   and adjusted time or normalized pseudotime is defined as         $\begin{matrix}         {{t_{a} = {\left( {\mu\quad c_{t}} \right)_{re}{\int_{0}^{t}\frac{\mathbb{d}t}{\mu_{w}c_{t}}}}}\quad} & (4)         \end{matrix}$     -   where the subscript ‘re’ refers to an arbitrary reference         condition selected for convenience.     -   The pressure difference for a slightly-compressible fluid         injection into a reservoir containing a slightly compressible         fluid may be calculated as         Δp(t)=p _(w)(t)−p _(i),   (5)     -   or for a slightly-compressible fluid injection in a reservoir         containing a compressible fluid, or a compressible fluid         injection in a reservoir containing a compressible fluid, use         the compressible reservoir fluid properties and calculate the         adjusted pseudopressure difference as         Δp _(a)(t)=p _(aw)(t)−p _(ai),   (6)     -   where $\begin{matrix}         {p_{a} = {\left( \frac{\mu\quad z}{p} \right)_{p_{i}}{\int_{0}^{p}{\frac{p{\mathbb{d}p}}{\mu\quad z}.}}}} & (7)         \end{matrix}$     -   where pseudopressure may be defined as $\begin{matrix}         {p_{a} = {\int_{0}^{p}\frac{p{\mathbb{d}p}}{\mu\quad z}}} & (8)         \end{matrix}$     -   and adjusted pseudopressure or normalized pseudopressure may be         defined as $\begin{matrix}         {p_{a} = {\left( \frac{\mu\quad z}{p} \right)_{re}{\int_{0}^{p}\frac{p{\mathbb{d}p}}{\mu\quad z}}}} & (9)         \end{matrix}$     -   where the subscript ‘re’ refers to an arbitrary reference         condition selected for convenience.     -   The reference conditions in the adjusted pseudopressure and         adjusted pseudotime definitions are arbitrary and different         forms of the solution may be derived by simply changing the         normalizing reference conditions.     -   Calculate the pressure-derivative plotting function as         $\begin{matrix}         {{{\Delta\quad p^{\prime}} = {\frac{\mathbb{d}\left( {\Delta\quad p} \right)}{\mathbb{d}\left( {\ln\quad\Delta\quad t} \right)} = {\Delta\quad p\quad\Delta\quad t}}},{or}} & (10) \\         {{{\Delta\quad p_{a}^{\prime}} = {\frac{\mathbb{d}\left( {\Delta\quad p_{a}} \right)}{\mathbb{d}\left( {\ln\quad t_{a}} \right)} = {\Delta\quad p_{a}t_{a}}}},} & (11)         \end{matrix}$     -   Transform the recorded variable-rate pressure falloff data to an         equivalent pressure if the rate were constant by integrating the         pressure difference with respect to time, which may be written         for a slightly compressible fluid as $\begin{matrix}         {{I\left( {\Delta\quad p} \right)} = {\int_{0}^{\Delta\quad t}{\left\lbrack {{p_{w}(\tau)} - p_{i}} \right\rbrack\quad{\mathbb{d}\tau}}}} & (12)         \end{matrix}$     -   or for a slightly-compressible fluid injected in a reservoir         containing a compressible fluid, or a compressible fluid         injection in a reservoir containing a compressible fluid, the         pressure-plotting function may be calculated as $\begin{matrix}         {{I\left( {\Delta\quad p_{a}} \right)} = {\int_{0}^{a}{\Delta\quad p_{a}\quad{{\mathbb{d}t_{a}}.}}}} & (13)         \end{matrix}$     -   Calculate the pressure-derivative plotting function as         $\begin{matrix}         {{{\Delta\quad p^{\prime}} = {\frac{\mathbb{d}\left( {\Delta\quad p} \right)}{\mathbb{d}\left( {\ln\quad\Delta\quad t} \right)} = {\Delta\quad p\quad\Delta\quad t}}},{or}} & (14) \\         {{{\Delta\quad p_{a}^{\prime}} = {\frac{\mathbb{d}\left( {\Delta\quad p_{a}} \right)}{\mathbb{d}\left( {\ln\quad t_{a}} \right)} = {\Delta\quad p_{a}t_{a}}}},} & (15)         \end{matrix}$     -   Prepare a log-log graph of I(Δp) versus Δt or I(Δp_(a)) versus         t_(a).     -   Prepare a log-log graph of Δp′ versus Δt or Δp′_(a) versus         t_(a).     -   Examine the storage behavior before and after closure.

Quantitative refracture-candidate diagnostic interpretation requires type-curve matching, or if pseudoradial flow is observed, after-closure analysis. After closure analysis may be performed by methods such as those disclosed in Gu, H. et al., Formation Permeability Determination Using Impulse-Fracture Injection, SPE 25425 (1993) or Abousleiman, Y., Cheng, A. H-D. and Gu, H., Formation Permeability Determination by Micro or Mini-Hydraulic Fracturing, J. OF ENERGY RESOURCES TECHNOLOGY, 116, No. 6, 104 (June 1994). After-closure analysis is preferable, because it does not require knowledge of fracture half length to calculate transmissibility. However, pseudoradial flow is unlikely to be observed during a relatively short pressure falloff, and type-curve matching may be necessary. From a pressure match point on a constant-rate type curve with constant before-closure storage, transmissibility may be calculated in field units as $\begin{matrix} {\frac{kh}{\mu} = {141.2(24){p_{wsD}(0)}{{C_{bc}\left( {p_{0} - p_{i}} \right)}\left\lbrack \frac{p_{bcD}\left( t_{D} \right)}{\int_{0}^{\Delta\quad t}{\left\lbrack {{p_{w}(\tau)} - p_{i}} \right\rbrack\quad{\mathbb{d}\tau}}} \right\rbrack}_{M}}} & (16) \end{matrix}$ or from an after-closure pressure match point using a variable-storage type curve $\begin{matrix} {\frac{kh}{\mu} = {141.2{(24)\left\lbrack {{{p_{wsD}(0)}C_{bc}} - {{p_{wsD}\left( \left( t_{c} \right)_{LfD} \right)}\left\lbrack {C_{bc} - C_{ac}} \right\rbrack}} \right\rbrack}{\left( {p_{0} - p_{i}} \right)\left\lbrack \frac{p_{acD}\left( t_{D} \right)}{\int_{0}^{\Delta\quad t}{\left\lbrack {{p_{w}(\tau)} - p_{i}} \right\rbrack\quad{\mathbb{d}\tau}}} \right\rbrack}_{M}}} & (17) \end{matrix}$

Quantitative interpretation has two limitations. First, the average reservoir pressure should be known for accurate equivalent constant-rate pressure and pressure derivative calculations, Eqs. 12 and 15. Second, fracture half length is required to calculate transmissibility. Fracture half length can be estimated by imaging or analytical methods, and the before-closure and after-closure storage coefficients may be calculated with methods such as those disclosed in Craig, D. P., Analytical Modeling of a Fracture-Injection/Falloff Sequence and the Development of a Refracture-Candidate Diagnostic Test, PhD dissertation, Texas A&M Univ., College Station, Tex. (2005) and the transmissibility estimated.

II. Fracture-Injection/Falloff Test Model

A fracture-injection/falloff test uses a short injection at a pressure sufficient to create and propagate a hydraulic fracture followed by an extended shut-in period. During the shut-in period, the induced fracture closes-which divides the falloff data into before-closure and after-closure portions. Separate theoretical descriptions of the before-closure and after-closure data have been presented as disclosed in Mayerhofer, M. J. and Economides, M. J., Permeability Estimation From Fracture Calibration Treatments, SPE 26039 (1993), Mayerhofer, M. J., Ehlig-Economides, C. A., and Economides, M. J., Pressure-Transient Analysis of Fracture-Calibration Tests, JPT, 229 (March 1995), Gu, H., et al., Formation Permeability Determination Using Impulse-Fracture Injection, SPE 25425 (1993), and Abousleiman, Y., Cheng, A. H-D., and Gu, H., Formation Permeability Determination by Micro or Mini-Hydraulic Fracturing, J. OF ENERGY RESOURCES TECHNOLOGY 116, No. 6, 104 (June 1994).

Mayerhofer and Economides and Mayerhofer et al. developed before-closure pressure-transient analysis while Gu et al. and Abousleiman et al. presented after-closure analysis theory. With before-closure and after-closure analysis, only specific and small portions of the pressure decline during a fracture-injection/falloff test sequence can be quantitatively analyzed.

Before-closure data, which can extend from a few seconds to several hours, can be analyzed for permeability and fracture-face resistance, and after-closure data can be analyzed for reservoir transmissibility and average reservoir pressure provided pseudoradial flow is observed. However, in a low permeability reservoir or when a relatively long fracture is created during the injection, an extended shut-in period—hours or possibly days—are typically required to observe pseudoradial flow. A quantitative transmissibility estimate from the after-closure pre-pseudoradial pressure falloff data, which represents the vast majority of the recorded pressure decline, is not possible with existing theoretical models.

A single-phase fracture-injection/falloff theoretical model accounting for fracture creation, fracture closure, and after-closure diffusion is presented below in Section III. The model accounts for fracture propagation as time-dependent storage, and the fracture-injection/falloff dimensionless pressure solution for a case with a propagating fracture, constant before-closure storage, and constant after-closure storage is written as $\begin{matrix} {{p_{wsD}\left( {\, t_{LfD}} \right)} = {{q_{wsD}\left\lbrack {{p_{pfD}\left( t_{LfD} \right)} - {p_{pfD}\left( {t_{LfD} - \left( t_{e} \right)_{LfD}} \right)}} \right\rbrack} - {C_{acD}{\int_{0}^{t_{LfD}}{{p_{fD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{p_{wsD}^{\prime}\left( \tau_{D} \right)}\quad{\mathbb{d}\tau_{D}}}}} - {\int_{0}^{{(t_{e})}_{LfD}}{{p_{pfD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{C_{pfD}\left( \tau_{D} \right)}{p_{wsD}^{\prime}\left( \tau_{D} \right)}{\mathbb{d}\tau_{D}}}} + {C_{bcD}{\int_{0}^{{(t_{e})}_{LfD}}{{p_{fD}^{\prime}\left( {t_{{LfD}\quad} - \tau_{D}} \right)}{p_{{wsD}\quad}^{\prime}\left( \tau_{D} \right)}\quad{\mathbb{d}\tau_{D}}}}} - {\left( {C_{bcD} - C_{acD}} \right){\int_{0}^{{(t_{c})}_{LfD}}{{p_{fD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{p_{wsD}^{\prime}\left( \tau_{D} \right)}\quad{\mathbb{d}\tau_{D}}}}}}} & (18) \end{matrix}$ where c_(beD) is the dimensionless before-closure storage, C_(acD) is the dimensionless after-closure storage, and C_(pfD) is the dimensionless propagating-fracture storage coefficient.

Two limiting-case solutions are also developed below in Section III for a short dimensionless injection time, (t_(e)e)_(LfD). The before-closure limiting-case solution, where (t_(e))_(LfD)□t_(LfD)<(t_(c))_(LfD) and (t_(c))_(LfD) is the dimensionless time at closure, is written as P _(wsD)(t_(LfD))=P _(wsD)(0)C _(bcDP′bcD)(t _(LfD))   (19) which is the slug test solution for a hydraulically fractured well with constant before-closure storage. The after-closure limiting-case solution, where t_(LfD) □(t_(c))_(LfD)□(t_(e))_(LfD), is written as P _(wsD)(t _(LfD))=[p _(wsD)(0)C _(bcD) −p _(wsD)((_(c))_(LfD))(C _(bcD) −c _(acD))]p′ _(acD)(t _(LfD))   (20) which is also a slug-test solution but includes variable storage.

Both single-phase limiting-case solutions presented, and other solutions presented by in Craig, D. P., Analytical Modeling of a Fracture-Injection/Falloff Sequence and the Development of a Refracture-Candidate Diagnostic Test, PhD dissertation, Texas A&M Univ., College Station, Tex. (2005) illustrate that a fracture-injection/falloff test can be analyzed as a slug test when the time of injection is short relative to the reservoir response.

In a study of the effects of a propagating fracture on injection/falloff data, Larsen, L. and Bratvold, R. B., Effects of Propagating Fractures on Pressure-Transient Injection and Falloff Data, SPE 20580 (1990), also demonstrated that when the filtrate and reservoir fluid properties differ, a single-phase pressure-transient model is appropriate if the depth of filtrate invasion is small. Thus, for fracture-injection/falloff sequence with a fracture created during a short injection period, the pressure falloff data can be analyzed as a slug test using single-phase pressure-transient solutions in the form of variable-storage constant-rate drawdown type curves.

Type curve analysis of the fracture-injection/falloff sequence uses transformation of the pressure recorded during the variable-rate falloff period to yield an equivalent “constant-rate” pressure as disclosed in Peres, A. M. M. et al., A New General Pressure-Analysis Procedure for Slug Tests, SPE FORMATION EVALUATION, 292 (December 1993). A type-curve match using new variable-storage constant-rate type curves can then be used to estimate transmissibility and identify flow periods for specialized analysis using existing before-closure and after-closure methods as presented in Craig, D. P., Analytical Modeling of a Fracture-Injection/Falloff Sequence and the Development of a Refracture-Candidate Diagnostic Test, PhD dissertation, Texas A&M Univ., College Station, Tex. (2005).

Using a derivation method analogous to that shown below in Section III, Craig develops a dimensionless pressure solution for a well in an infinite slab reservoir with an open fracture supported by initial reservoir pressure that closes during a constant-rate drawdown with constant before-closure and after-closure storage, which is written as $\begin{matrix} {{p_{wcD}\left( t_{LfD} \right)} = {{p_{acD}\left( t_{LfD} \right)} - {\left( {C_{bcD} - C_{acD}} \right){\int_{0}^{{(t_{c})}_{LfD}}{{p_{acD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{p_{wcD}^{\prime}\left( \tau_{D} \right)}\quad{\mathbb{d}\tau_{D}}}}}}} & (21) \end{matrix}$ where P_(wcD) denotes that the pressure solution is for a constant rate and p_(acD) is the dimensionless pressure solution for a constant-rate drawdown with constant after-closure storage, which is written in the Laplace domain as $\begin{matrix} {{{\overset{\_}{p}}_{acD} = \frac{{\overset{\_}{p}}_{fD}}{1 + {s^{2}C_{acD}{\overset{\_}{p}}_{fd}}}},} & (22) \end{matrix}$ and p _(fD) is the Laplace domain reservoir solution for a reservoir producing from a single vertical infinite- or finite-conductivity fracture.

FIG. 4 shows a graph of dimensionless pressure and pressure derivative versus dimensionless time and illustrates a case that exhibits constant before-closure storage, C_(bcD)=10, and constant after-closure storage, C_(acD)=1, with variable dimensionless closure time.

Fracture volume before closure is greater than the residual fracture volume after closure, V_(f)>V_(fr), and the change in fracture volume with respect to pressure is positive. Thus before-closure storage, when a fracture is open and closing, is greater than after-closure storage, which is written as $\begin{matrix} {{{c_{f}V_{f}} + \frac{\mathbb{d}V_{f}}{\mathbb{d}p_{w}}} > {c_{f}{V_{{fr}\quad}.}}} & (23) \end{matrix}$

Consequently, decreasing storage as shown in FIG. 4 should be expected during a constant-rate drawdown with a closing fracture as has been demonstrated for a closing waterflood-induced fracture during a falloff period by Koning, E. J. L. and Niko, H., Fractured Water-Injection Wells: A Pressure Falloff Test for Determining Fracturing Dimensions, SPE 14458 (1985), Koning, E. J. L., Waterflooding Under Fracturing Conditions, PhD Thesis, Delft Technical University (1988), van den Hoek, P. J., Pressure Transient Analysis in Fractured Produced Water Injection Wells, SPE 77946 (2002), and van den Hoek, P. J., A Novel Methodology to Derive the Dimensions and Degree of Containment of Waterflood-Induced Fractures From Pressure Transient Analysis, SPE 84289 (2003).

In certain instances, storage may appear to increase during a constant-rate drawdown with a closing fracture. A variable wellbore storage model for reservoirs with natural fractures of limited extent in communication with the wellbore was disclosed in Spivey, J. P. and Lee, W. J., Variable Wellbore Storage Models for a Dual-Volume Wellbore, SPE 56615 (1999). The variable storage model includes a natural fracture storage coefficient and natural fracture skin affecting communication with the reservoir, and a wellbore storage coefficient and a completion skin affecting communication between the natural fractures and the wellbore. The Spivey and Lee radial geometry model with natural fractures of limited extent in communication with the wellbore demonstrates that storage can appear to increase when the completion skin is greater than zero.

The concept of Spivey and Lee may be extended to a constant-rate drawdown for a well with a vertical hydraulic fracture by incorporating fracture-face and choked fracture skin as described by Cinco-Ley, H. and Samaniego-V., F., Transient Pressure Analysis: Finite Conductivity Fracture Case Versus Damage Fracture Case, SPE 10179 (1981). The problem is formulated by first considering only wellbore storage and writing a dimensionless material balance equation as $\begin{matrix} {{q_{D} = {q_{wD} - {C_{D}\frac{\mathbb{d}p_{wD}}{\mathbb{d}t_{LfD}}}}},} & (24) \end{matrix}$ where C_(D) is the dimensionless wellbore storage coefficient written as $\begin{matrix} {{C_{D} = \frac{c_{wd}V_{wb}}{2\quad\pi\quad\phi\quad c_{t}{hL}_{f}^{2}}},} & (25) \end{matrix}$

The dimensionless material balance equation is combined with the superposition integral in the Laplace domain, and the wellbore solution is written as $\begin{matrix} {{{\overset{\_}{p}}_{wD} = \frac{{s{\overset{\_}{p}}_{wfD}} + \left( S_{fs} \right)_{ch}}{s\left\lbrack {1 + {{sC}_{D}\left\lbrack {{s{\overset{\_}{p}}_{wfD}} + \left( S_{fs} \right)_{ch}} \right\rbrack}} \right\rbrack}},} & (26) \end{matrix}$ where (S_(fs))_(ch) is the choked fracture skin and p _(wfD) is the Laplace domain dimensionless pressure solution outside of the wellbore in the fracture.

Before fracture closure, the dimensionless pressure in the fracture outside of the wellbore is simply a function of before-closure fracture storage and fracture-face skin, S_(fs), and may be written in the Laplace domain as $\begin{matrix} {{\overset{\_}{p}}_{wfD} = {\frac{{s{\overset{\_}{p}}_{fD}} + S_{fs}}{s\left\lbrack {1 + {{sC}_{fbcD}\left\lbrack {{s{\overset{\_}{p}}_{fD}} + S_{fs}} \right\rbrack}} \right\rbrack}.}} & (27) \end{matrix}$ where the dimensionless before-closure fracture storage is written as $\begin{matrix} {C_{fbcD} = \frac{C_{fbc}}{2{\pi\phi c}_{t}h\quad L_{f}^{2}}} & (28) \end{matrix}$ and the before-closure fracture storage coefficient is written as $\begin{matrix} {C_{fbc} = {{2c_{f}V_{f}} + {2\frac{\mathbb{d}V_{f}}{\mathbb{d}p_{w}}}}} & (29) \end{matrix}$

The before-closure dimensionless wellbore pressure accounting for fracture-face skin, before-closure storage, choked-fracture skin, and wellbore storage is solved by numerically inverting the Laplace domain solution, Eq. 26 and Eq. 27.

After fracture closure the solution outside of the wellbore accounting for variable fracture storage is analogous to the dimensionless pressure solution for a well in an infinite slab reservoir with an open fracture supported by initial reservoir pressure that closes during the drawdown with constant before-closure and after-closure storage. The solution may be written as $\begin{matrix} {{p_{wfD}\left( t_{LfD} \right)} = {{p_{facD}\left( t_{LfD} \right)} - {\left( {C_{fbcD} - C_{facD}} \right){\int_{0}^{{(t_{c})}_{LfD}}{{p_{facD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{p_{wfD}^{\prime}\left( \tau_{D} \right)}{\mathbb{d}\tau_{D}}}}}}} & (30) \end{matrix}$ where the dimensionless after-closure fracture storage is written as $\begin{matrix} {C_{facD} = \frac{2c_{f}V_{fr}}{2{\pi\phi c}_{t}h\quad L_{f}^{2}}} & (31) \end{matrix}$ and p_(facD) is the dimensionless pressure solution in the fracture for a constant-rate drawdown with constant storage, which is written in the Laplace domain as $\begin{matrix} {{\overset{\_}{p}}_{facD} = {\frac{{s\quad{\overset{\_}{p}}_{fD}} + S_{fs}}{s\left\lbrack {1 + {s\quad{C_{facD}\left( {{s\quad{\overset{\_}{p}}_{fD}} + S_{fs}} \right)}}} \right\rbrack}.}} & (32) \end{matrix}$

After fracture closure, the dimensionless wellbore pressure solution is obtained by evaluating a time-domain descretized solution of the dimensionless pressure outside of the wellbore and in the fracture at each time (t_(LfD))_(n). With the time-domain dimensionless pressure outside of the wellbore in the fracture known, the Laplace domain solution, which is written as $\begin{matrix} {{\overset{\_}{p}}_{wfD} = {{\overset{\_}{p}}_{facD} - {\left( {C_{fbcD} - C_{facD}} \right)s\quad{\overset{\_}{p}}_{facD}{\int_{0}^{{(t_{c})}_{LfD}}{{\mathbb{e}}^{- {st}_{LfD}}{p_{wfD}^{\prime}\left( t_{LfD} \right)}{\mathbb{d}t_{LfD}}}}}}} & (33) \end{matrix}$ can be evaluated numerically and combined with the Laplace domain wellbore solution, Eq. 26, and numerically inverted to the time domain as described in Craig, D. P., Analytical Modeling of a Fracture-Injection/Falloff Sequence and the Development of a Refracture-Candidate Diagnostic Test, PhD dissertation, Texas A&M Univ., College Station, Tex. (2005).

FIG. 5 presents a log-log graph of dimensionless pressure and pressure derivative versus dimensionless time without fracture-face skin, S_(fs)=0, but with variable choked-fracture skin, (S_(fs))_(ch)={0.05, 1, 5}. FIG. 5 demonstrates that storage appears to increase during a constant-rate drawdown in a well with a closing fracture and choked-fracture skin.

III. Theoretical Model A—Fracture-Injection/Falloff Solution in a Reservoir without a Pre-Existing Fracture

Assume a slightly compressible fluid fills the wellbore and fracture and is injected at a constant rate and at a pressure sufficient to create a new hydraulic fracture or dilate an existing fracture. As the term is used herein, the term compressible fluid refers to gases whereas the term slightly compressible fluid refers to liquids. A mass balance during a fracture injection may be written as $\begin{matrix} {{{{\overset{m_{in}}{\overset{︷}{q_{w}B\quad\rho}} - \overset{m_{out}}{\overset{︷}{q_{\ell}B_{r}\rho_{r}}}} = \overset{Storage}{\overset{︷}{{V_{w\quad b}\frac{\mathbb{d}\rho_{w\quad b}}{\mathbb{d}t}} + {2\frac{\mathbb{d}\left( {V_{f}\rho_{f}} \right)}{\mathbb{d}t}}}}},}\quad} & \left( {A\text{-}1} \right) \end{matrix}$ where q_(l) is the fluid leakoff rate into the reservoir from the fracture, q_(l)=q_(sf), and V_(f) is the fracture volume.

A material balance equation may be written assuming a constant density, ρ=ρ_(wb)=ρ_(f)=ρ_(r), and a constant formation volume factor, B=B_(r), as $\begin{matrix} {q_{sf} = {q_{w} - {\frac{1}{B}\left( {{c_{w\quad b}V_{w\quad b}} + {2c_{f}V_{f}} + {2\frac{\mathbb{d}V_{f}}{\mathbb{d}p_{w}}}} \right){\frac{\mathbb{d}p_{w}}{\mathbb{d}t}.}}}} & \left( {A\text{-}2} \right) \end{matrix}$

During a constant rate injection with changing fracture length and width, the fracture volume may be written as V _(f)(p _(w)(t))=h _(f) L(p _(w)(t))ŵ _(f)(p _(w)(t))   (A-3) and the propagating-fracture storage coefficient may be written as $\begin{matrix} {{c_{pf}\left( {p_{w}(t)} \right)} = {{c_{w\quad b}V_{w\quad b}} + {2c_{f}{V_{f}\left( {p_{w}(t)} \right)}} + {2{\frac{\mathbb{d}{V_{f}\left( {p_{w}(t)} \right)}}{\mathbb{d}p_{w}}.}}}} & \left( {A\text{-}4} \right) \end{matrix}$

The dimensionless wellbore pressure for a fracture-injection/falloff may be written as $\begin{matrix} {{{p_{wsD}\left( t_{LfD} \right)} = \frac{{p_{w}\left( t_{LfD} \right)} - p_{i}}{p_{0} - p_{i}}},} & \left( {A\text{-}5} \right) \end{matrix}$ where P_(i) is the initial reservoir pressure and p₀ is an arbitrary reference pressure. At time zero, the wellbore pressure is increased to the “opening” pressure, P_(w0), which is generally set equal to P₀, and the dimensionless wellbore pressure at time zero may be written as $\begin{matrix} {{p_{wsD}(0)} = {\frac{p_{w\quad 0} - p_{i}}{p_{0} - p_{i}}.}} & \left( {A\text{-}6} \right) \end{matrix}$

Define dimensionless time as $\begin{matrix} {{t_{LfD} = \frac{kt}{{\phi\mu}\quad c_{t}L_{f}^{2}}},} & \left( {A\text{-}7} \right) \end{matrix}$ where L_(f) is the fracture half-length at the end of pumping. The dimensionless reservoir flow rate may be defined as $\begin{matrix} {{q_{sD} = \frac{q_{sf}B\quad\mu}{2\pi\quad{{kh}\left( {p_{0} - p_{i}} \right)}}},} & \left( {A\text{-}8} \right) \end{matrix}$ and the dimensionless well flow rate may be defined as $\begin{matrix} {{q_{wsD} = \frac{q_{w}B\quad\mu}{2\pi\quad{{kh}\left( {p_{0} - p_{i}} \right)}}},} & \left( {A\text{-}9} \right) \end{matrix}$ where q_(w) is the well injection rate.

With dimensionless variables, the material balance equation for a propagating fracture during injection may be written as $\begin{matrix} {q_{sD} = {q_{wsD} - {\frac{C_{pf}\left( {p_{w}(t)} \right)}{2{\pi\phi}\quad c_{t}{hL}_{f}^{2}}{\frac{\mathbb{d}p_{wsD}}{\mathbb{d}t_{LfD}}.}}}} & \left( {A\text{-}10} \right) \end{matrix}$

Define a dimensionless fracture storage coefficient as $\begin{matrix} {{C_{f\quad D} = \frac{C_{pf}\left( {p_{w}(t)} \right)}{2{\pi\phi}\quad c_{t}{hL}_{f}^{2}}},} & \left( {A\text{-}11} \right) \end{matrix}$

and the dimensionless material balance equation during an injection at a pressure sufficient to create and extend a hydraulic fracture may be written as $\begin{matrix} {q_{sD} = {q_{wsD} - {{C_{pfD}\left( {p_{wsD}\left( t_{LfD} \right)} \right)}{\frac{\mathbb{d}p_{wsD}}{\mathbb{d}t_{LfD}}.}}}} & \left( {A\text{-}12} \right) \end{matrix}$

Using the technique of Correa and Ramey as disclosed in Correa, A. C. and Ramey, H. J., Jr., Combined Effects of Shut-In and Production: Solution With a New Inner Boundary Condition, SPE 15579 (1986) and Correa, A. C. and Ramey, H. J., Jr., A Method for Pressure Buildup Analysis of Drillstem Tests, SPE 16802 (1987), a material balance equation valid at all times for a fracture-injection/falloff sequence with fracture creation and extension and constant after-closure storage may be written as $\begin{matrix} {q_{sD} = {q_{wsD} - {U_{{(t_{e})}_{LfD}}q_{wsD}} - {{C_{pfD}\left( {p_{wsD}\left( t_{LfD} \right)} \right)}\frac{\mathbb{d}p_{wsD}}{\mathbb{d}t_{LfD}}} + {{U_{{(t_{e})}_{LfD}}\left\lbrack {{C_{pfD}\left( {p_{wsD}\left( t_{LfD} \right)} \right)} - C_{bcD}} \right\rbrack}\frac{\mathbb{d}p_{wsD}}{\mathbb{d}t_{LfD}}} + {{U_{{(t_{c})}_{LfD}}\left\lbrack {C_{bcD} - C_{acD}} \right\rbrack}\frac{\mathbb{d}p_{wsD}}{\mathbb{d}t_{LfD}}}}} & \left( {A\text{-}13} \right) \end{matrix}$ where the unit step function is defined as $\begin{matrix} {U_{a} = \left\{ \begin{matrix} {0,} & {t < a} \\ {1,} & {t > {a.}} \end{matrix} \right.} & \left( {A\text{-}14} \right) \end{matrix}$

The Laplace transform of the material balance equation for an injection with fracture creation and extension is written after expanding and simplifying as $\begin{matrix} {{\overset{\_}{q}}_{sD} = {\frac{q_{wsD}}{s} - {q_{wsD}\frac{{\mathbb{e}}^{- {s{(t_{e})}}_{LfD}}}{s}} - {\int_{0}^{{(t_{e})}_{LfD}}{{\mathbb{e}}^{{- s}\quad t_{LfD}}{C_{pfD}\left( {p_{wsD}\left( t_{LfD} \right)} \right)}{p_{wsD}^{\prime}\left( t_{LfD} \right)}{\mathbb{d}t_{LfD}}}} - {s\quad C_{acD}{\overset{\_}{p}}_{wsD}} + {{p_{wsD}(0)}C_{acD}} + {\int_{0}^{{(t_{e})}_{LfD}}{{\mathbb{e}}^{{- s}\quad t_{LfD}}C_{bcD}{p_{wsD}^{\prime}\left( t_{LfD} \right)}{\mathbb{d}t_{LfD}}}} - {\left( {C_{bcD} - C_{acD}} \right){\int_{0}^{{(t_{c})}_{LfD}}{{\mathbb{e}}^{{- s}\quad t_{LfD}}{p_{wsD}^{\prime}\left( t_{LfD} \right)}{\mathbb{d}t_{LfD}}}}}}} & \left( {A\text{-}15} \right) \end{matrix}$

With fracture half length increasing during the injection, a dimensionless pressure solution may be required for both a propagating and fixed fracture half-length. A dimensionless pressure solution may developed by integrating the line-source solution, which may be written as $\begin{matrix} {{{\overset{\_}{\Delta\quad p}}_{ls} = {\frac{\overset{\sim}{q}\quad\mu}{2\pi\quad{ks}}{K_{0}\left( {r_{D}\sqrt{u}} \right)}}},} & \left( {A\text{-}16} \right) \end{matrix}$ from x_(w)− L(s) and x_(w)+ L(s) with respect to x′_(w) where u=sf(s), and f(s)=1 for a single-porosity reservoir. Here, it is assumed that the fracture half length may be written as a function of the Laplace variable, s, only. In terms of dimensionless variables, x′_(wD)=x′_(w)/L_(f) and dx′_(w)=L_(f)dx′_(wD)′ the line-source solution is integrated from x_(wD)− L _(fD)(s) to x_(wD)+ L _(fD)(s), which may be written as $\begin{matrix} {\overset{\_}{\Delta\quad p} = {\frac{\overset{\sim}{q}\quad\mu\quad L_{f}}{2\pi\quad{ks}}{\int_{x_{wD} - {{\overset{\_}{L}}_{fD}{(s)}}}^{x_{wD} + {{\overset{\_}{L}}_{fD}{(s)}}}{{K_{0}\left\lbrack {\sqrt{u}\sqrt{\left( {x_{D} - x_{wD}^{\prime}} \right)^{2} + \left( {y_{D} - y_{wD}} \right)^{2}}} \right\rbrack}{\mathbb{d}x_{wD}^{\prime}}}}}} & \left( {A\text{-}17} \right) \end{matrix}$

Assuming that the well center is at the origin, x_(wD)=y_(wD)=0, $\begin{matrix} {\overset{\_}{\Delta\quad p} = {\frac{\overset{\sim}{q}\quad\mu\quad L_{f}}{2\pi\quad{ks}}{\int_{- {{\overset{\_}{L}}_{fD}{(s)}}}^{{\overset{\_}{L}}_{fD}{(s)}}{{K_{0}\left\lbrack {\sqrt{u}\sqrt{\left( {x_{D} - x_{wD}^{\prime}} \right)^{2} + \left( y_{D} \right)^{2}}} \right\rbrack}{\mathbb{d}x_{wD}^{\prime}}}}}} & \left( {A\text{-}18} \right) \end{matrix}$

Assuming constant flux, the flow rate in the Laplace domain may be written as q (s)=2 qh L( s),   (A-19) and the plane-source solution may be written in dimensionless terms as $\begin{matrix} {{{\overset{\_}{p}}_{D} = {\frac{{\overset{\_}{q}}_{D}(s)}{{\overset{\_}{L}}_{fD}(s)}\frac{1}{2s}{\int_{- {{\overset{\_}{L}}_{fD}{(s)}}}^{{\overset{\_}{L}}_{fD}{(s)}}{{K_{0}\left\lbrack {\sqrt{u}\sqrt{\left( {x_{D} - \alpha} \right)^{2} + \left( y_{D} \right)^{2}}} \right\rbrack}{\mathbb{d}\alpha}}}}},} & \left( {A\text{-}20} \right) \\ {where} & \quad \\ {{{\overset{\_}{p}}_{D} = \frac{2\pi\quad{kh}\quad\overset{\_}{\Delta\quad p}}{\overset{\_}{q\quad}\mu}},} & \left( {A\text{-}21} \right) \\ {{{{\overset{\_}{L}}_{fD}(s)} = \frac{L(s)}{L_{f}}},} & \left( {A\text{-}22} \right) \end{matrix}$ and defining the total flow rate as q _(t)(s), the dimensionless flow rate may be written as $\begin{matrix} {{{\overset{\_}{q}}_{D}(s)} = {\frac{\overset{\_}{q}(s)}{{\overset{\_}{q}}_{t}(s)}.}} & \left( {A\text{-}23} \right) \end{matrix}$

It may be assumed that the total flow rate increases proportionately with respect to increased fracture half-length such that q _(D)(s)=1. The solution is evaluated in the plane of the fracture, and after simplifying the integral using the identity of Ozkan and Raghavan as disclosed in Ozkan, E. and Raghavan, R., New Solutions for Well-Test-Analysis Problems: Part 2—Computational Considerations and Applications, SPEFE, 369 (September 1991), the dimensionless uniform-flux solution in the Laplace domain for a variable fracture half-length may be written as $\begin{matrix} {{\overset{\_}{p}}_{pfD} = {\frac{1}{{\overset{\_}{L}}_{fD}(s)}{\frac{1}{2s\sqrt{u}}\left\lbrack {{\int_{0}^{\sqrt{u}{({{{\overset{\_}{L}}_{fD}{(s)}} + x_{D}})}}{{K_{0}\lbrack z\rbrack}{\mathbb{d}z}}} + {\int_{0}^{\sqrt{u}{({{{\overset{\_}{L}}_{fD}{(s)}} - x_{D}})}}{{K_{0}\lbrack z\rbrack}{\mathbb{d}z}}}} \right\rbrack}}} & \left( {A\text{-}24} \right) \end{matrix}$ and the infinite conductivity solution may be obtained by evaluating the uniform-flux solution at x_(D)=0.732 L _(fD)(s) and may be written as $\begin{matrix} {{\overset{\_}{p}}_{pfD} = {\frac{1}{{\overset{\_}{L}}_{fD}(s)}\frac{1}{2s\sqrt{u}}{\quad\left\lbrack {{\int_{0}^{\sqrt{u}{{\overset{\_}{L}}_{fD}{(s)}}{({1 + 0.732})}}{{K_{0}\lbrack z\rbrack}{\mathbb{d}z}}} + {\int_{0}^{\sqrt{u}{{\overset{\_}{L}}_{fD}{(s)}}{({1 - 0.732})}}{{K_{0}\lbrack z\rbrack}{\mathbb{d}z}}}} \right\rbrack}}} & \left( {A\text{-}25} \right) \end{matrix}$

The Laplace domain dimensionless fracture half-length varies between 0 and 1 during fracture propagation, and using a power-model approximation as shown in Nolte, K. G., Determination of Fracture Parameters From Fracturing Pressure Decline, SPE 8341 (1979), the Laplace domain dimensionless fracture half-length may be written as $\begin{matrix} {{{{\overset{\_}{L}}_{fD}(s)} = {\frac{\overset{\_}{L}(s)}{{\overset{\_}{L}}_{f}\left( s_{e} \right)} = \left( \frac{s_{e}}{s} \right)^{\alpha}}},} & \left( {A\text{-}26} \right) \end{matrix}$ where S_(e) is the Laplace domain variable at the end of pumping. The Laplace domain dimensionless fracture half length may be written during propagation and closure as $\begin{matrix} {{{\overset{\_}{L}}_{fD}(s)} = \left\{ \begin{matrix} \left( \frac{s_{e}}{s} \right)^{\alpha} & {s_{e} < s} \\ 1 & {s_{e} \geq {s.}} \end{matrix} \right.} & \left( {A\text{-}27} \right) \end{matrix}$ where the power-model exponent ranges from α=½ for a low efficiency (high leakoff) fracture and α=1 for a high efficiency (low leakoff) fracture.

During the before-closure and after-closure period—when the fracture half-length is unchanging—the dimensionless reservoir pressure solution for an infinite conductivity fracture in the Laplace domain may be written as $\begin{matrix} {{\overset{\_}{p}}_{fD} = {{\frac{1}{2s\sqrt{u}}\left\lbrack {{\int_{0}^{\sqrt{u}{({1 + 0.732})}}{{K_{0}\lbrack z\rbrack}{\mathbb{d}z}}} + {\int_{0}^{\sqrt{u}{({1 - 0.732})}}{{K_{0}\lbrack z\rbrack}{\mathbb{d}z}}}} \right\rbrack}.}} & \left( {A\text{-}28} \right) \end{matrix}$

The two different reservoir models, one for a propagating fracture and one for a fixed-length fracture, may be superposed to develop a dimensionless wellbore pressure solution by writing the superposition integrals as $\begin{matrix} {{p_{wsD} = {{\int_{0}^{t_{LfD}}{{q_{pfD}\left( \tau_{D} \right)}\frac{\mathbb{d}{p_{pfD}\left( {t_{LfD} - \tau_{D}} \right)}}{\mathbb{d}t_{LfD}}{\mathbb{d}\tau_{D}}}} + {\int_{0}^{t_{LfD}}{{q_{fD}\left( \tau_{D} \right)}\frac{\mathbb{d}{p_{fD}\left( {t_{LfD} - \tau_{D}} \right)}}{\mathbb{d}t_{LfD}}{\mathbb{d}\tau_{D}}}}}},} & \left( {A\text{-}29} \right) \end{matrix}$ where q_(pfD)(t_(LfD)) is the dimensionless flow rate for the propagating fracture model, and q_(fD)(t_(LfD)) is the dimensionless flow rate with a fixed fracture half-length model used during the before-closure and after-closure falloff period. The initial condition in the fracture and reservoir is a constant initial pressure, p_(D)=(t_(LfD))=p_(pfD)(t_(LfD))=p_(fD)(t_(LfD))=0, and with the initial condition, the Laplace transform of the superposition integral is written as p _(wsD) = q _(pfD) sp _(pfD) + q _(fD) sp _(fD).   (A-30)

The Laplace domain dimensionless material balance equation may be split into injection and falloff parts by writing as q _(sD) = q _(pfD) + q _(fD).   (A-31) where the dimensionless reservoir flow rate during fracture propagation may be written as $\begin{matrix} {{{\overset{\_}{q}}_{pfD} = {\frac{q_{wsD}}{s} - {q_{wsD}\frac{{\mathbb{e}}^{- {s{(t_{e})}}_{LfD}}}{s}} - {\int_{0}^{{(t_{e})}_{LfD}}{{\mathbb{e}}^{{- s}\quad t_{LfD}}{C_{pfD}\left( {p_{wsD}\left( t_{LfD} \right)} \right)}{p_{wsD}^{\prime}\left( t_{LfD} \right)}{\mathbb{d}t_{LfD}}}}}},} & \left( {A\text{-}32} \right) \end{matrix}$ and the dimensionless before-closure and after-closure fracture flow rate may be written as $\begin{matrix} {{\overset{\_}{q}}_{fD} = {\begin{bmatrix} {{{p_{wD}(0)}C_{acD}} - {s\quad C_{acD}{\overset{\_}{p}}_{wsD}} +} \\ {{C_{bcD}{\int_{0}^{{(t_{e})}_{LfD}}{{\mathbb{e}}^{{- s}\quad t_{LfD}}{p_{wsD}^{\prime}\left( t_{LfD} \right)}{\mathbb{d}t_{LfD}}}}} -} \\ {\left( {C_{bcD} - C_{acD}} \right){\int_{0}^{{(t_{c})}_{LfD}}{{\mathbb{e}}^{{- s}\quad t_{LfD}}{p_{wsD}^{\prime}\left( t_{LfD} \right)}{\mathbb{d}t_{LfD}}}}} \end{bmatrix}.}} & \left( {A\text{-}33} \right) \end{matrix}$

Using the superposition principle to develop a solution requires that the pressure-dependent dimensionless propagating-fracture storage coefficient be written as a function of time only. Let fracture propagation be modeled by a power model and written as $\begin{matrix} {\frac{A(t)}{A_{f}} = {\frac{h_{f}{L(t)}}{h_{f}L_{f}} = {\left( \frac{t}{t_{e}} \right)^{\alpha}.}}} & \left( {A\text{-}34} \right) \end{matrix}$

Fracture volume as a function of time may be written as V _(f)(p _(w)(t))=h _(f) L(p _(w)(t)ŵ _(f)(p _(w)(t))   (A-35) which, using the power model, may also be written as $\begin{matrix} {{V_{f}\left( {p_{w}(t)} \right)} = {h_{f}L_{f}\frac{\left( {{p_{w}(t)} - p_{c}} \right)}{S_{f}}{\left( \frac{t}{t_{e}} \right)^{\alpha}.}}} & \left( {A\text{-}36} \right) \end{matrix}$

The derivative of fracture volume with respect to wellbore pressure may be written as $\begin{matrix} {\frac{\mathbb{d}{V_{f}\left( {p_{w}(t)} \right)}}{\mathbb{d}p_{w}} = {\frac{h_{f}L_{f}}{S_{f}}{\left( \frac{t}{t_{e}} \right)^{\alpha}.}}} & \left( {A\text{-}37} \right) \end{matrix}$

Recall the propagating-fracture storage coefficient may be written as $\begin{matrix} {{{C_{pf}\left( {p_{w}(t)} \right)} = {{c_{wb}V_{wb}} + {2c_{f}{V_{f}\left( {p_{w}(t)} \right)}} + {2\frac{\mathbb{d}{V_{f}\left( {p_{w}(t)} \right)}}{\mathbb{d}p_{w}}}}},} & \left( {A\text{-}38} \right) \end{matrix}$ which, with power-model fracture propagation included, may be written as $\begin{matrix} {{C_{pf}\left( {p_{w}(t)} \right)} = {{c_{wb}V_{wb}} + {2\frac{h_{f}L_{f}}{S_{f}}\left( \frac{t}{t_{e}} \right)^{\alpha}{\left( {{c_{f}p_{n}} + 1} \right).}}}} & \left( {A\text{-}39} \right) \end{matrix}$

As noted by Hagoort, J., Waterflood-induced hydraulic fracturing, PhD Thesis, Delft Tech. Univ. (1981), Koning, E. J. L. and Niko, H., Fractured Water-Injection Wells: A Pressure Falloff Test for Determining Fracturing Dimensions, SPE 14458 (1985), Koning, E. J. L., Waterflooding Under Fracturing Conditions, PhD Thesis, Delft Technical University (1988), van den Hoek, P. J., Pressure Transient Analysis in Fractured Produced Water Injection Wells, SPE 77946 (2002), and van den Hoek, P. J., A Novel Methodology to Derive the Dimensions and Degree of Containment of Waterflood-Induced Fractures From Pressure Transient Analysis, SPE 84289 (2003), C_(f)P_(n)(t)□ 1, and the propagating-fracture storage coefficient may be written as $\begin{matrix} {{{C_{pf}\left( t_{LfD} \right)} = {{c_{wb}V_{wb}} + {2\frac{A_{f}}{S_{f}}\left( \frac{t_{LfD}}{\left( t_{e} \right)_{LfD}} \right)^{\alpha}}}},} & \left( {A\text{-}40} \right) \end{matrix}$ which is not a function of pressure and allows the superposition principle to be used to develop a solution.

Combining the material balance equations and superposition integrals results in $\begin{matrix} {{\overset{\_}{p}}_{wsD} = {{q_{wsD}{\overset{\_}{p}}_{pfD}} - {q_{wsD}{\overset{\_}{p}}_{pfD}{\mathbb{e}}^{- {s{(t_{e})}}_{LfD}}} - {C_{acD}\left\lbrack {s\quad{{\overset{\_}{p}}_{fD}\left( {{s{\overset{\_}{p}}_{wsD}} - {p_{wD}(0)}} \right)}} \right\rbrack} - {s{\overset{\_}{p}}_{pfD}{\int_{0}^{{(t_{e})}_{LfD}}{{\mathbb{e}}^{- {st}_{LfD}}{C_{pfD}\left( t_{LfD} \right)}{p_{wsD}^{\prime}\left( t_{LfD} \right)}{\mathbb{d}t_{LfD}}}}} + {s{\overset{\_}{p}}_{fD}C_{bcD}{\int_{0}^{{(t_{e})}_{LfD}}{{\mathbb{e}}^{- {st}_{LfD}}{p_{wsD}^{\prime}\left( t_{LfD} \right)}}}} - {s{\overset{\_}{p}}_{fD}{\int_{0}^{{(t_{c})}_{LfD}}{{{\mathbb{e}}^{- {st}_{LfD}}\left\lbrack {C_{bcD} - C_{acD}} \right\rbrack}{p_{wsD}^{\prime}\left( t_{LfD} \right)}{\mathbb{d}t_{LfD}}}}}}} & \left( {A\text{-}41} \right) \end{matrix}$ and after inverting to the time domain, the fracture-injection/falloff solution for the case of a propagating fracture, constant before-closure storage, and constant after-closure storage may be written as $\begin{matrix} \begin{matrix} {{p_{wsD}\left( t_{LfD} \right)} = {{q_{wsD}\left\lbrack {{p_{pfD}\left( t_{LfD} \right)} - {p_{pfD}\left( {t_{LfD} - \left( t_{\mathbb{e}} \right)_{LfD}} \right)}} \right\rbrack} -}} \\ {{C_{acD}{\int_{0}^{t_{LfD}}{{p_{fD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{p_{wsD}^{\prime}\left( \tau_{D} \right)}{\mathbb{d}\tau_{D}}}}} -} \\ {{\int_{0}^{{(t_{\mathbb{e}})}_{LfD}}{{p_{pfD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}\quad{C_{pfD}\left( \tau_{D} \right)}{p_{wsD}^{\prime}\left( \tau_{D} \right)}{\mathbb{d}\tau_{D}}}} +} \\ {{C_{bcD}{\int_{0}^{{(t_{\mathbb{e}})}_{LfD}}{{p_{fD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{p_{wsD}^{\prime}\left( \tau_{D} \right)}{\mathbb{d}\tau_{D}}}}} -} \\ {\left( {C_{bcD} - C_{acD}} \right){\int_{0}^{{(t_{c})}_{LfD}}{{p_{fD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{p_{wsD}^{\prime}\left( \tau_{D} \right)}{\mathbb{d}\tau_{D}}}}} \end{matrix} & \left( {A\text{-}42} \right) \end{matrix}$

Limiting-case solutions may be developed by considering the integral term containing propagating-fracture storage. When t_(LfD)□(t_(e))_(LfD), the propagating-fracture solution derivative may be written as P′ _(pfD)(t _(LfD)−τ_(D))≡p′ _(pfD)(_(LfD))   (A-43) and the fracture solution derivative may also be approximated as P′ _(fD)(t _(LfD)−τ_(D))≡p′ _(fD)(_(LfD))   (A-43)

The definition of the dimensionless propagating-fracture solution states that when t_(LfD)>(t_(e))_(LfD), the propagating-fracture and fracture solution are equal, and p′_(pfD)(t_(LfD))=p′_(fD)(t_(LfD)). Consequently, for t_(LfD)□(t_(e))_(LfD), the dimensionless wellbore pressure solution may be written as $\begin{matrix} \begin{matrix} {{p_{wsD}\left( t_{LfD} \right)} =} \\ \begin{bmatrix} {{{p_{fD}^{\prime}\left( t_{LfD} \right)}{\int_{0}^{{(t_{\mathbb{e}})}_{LfD}}{\left\lbrack {C_{bcD} - {C_{fD}\left( \tau_{D} \right)}} \right\rbrack{p_{wsD}^{\prime}\left( \tau_{D} \right)}{\mathbb{d}t_{D}}}}} -} \\ {{C_{acD}{\int_{0}^{t_{LfD}}{{p_{fD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{p_{wsD}^{\prime}\left( \tau_{D} \right)}{\mathbb{d}\tau_{D}}}}} -} \\ {\left( {C_{bcD} - C_{acD}} \right){\int_{0}^{{(t_{c})}_{LfD}}{{p_{fD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{p_{wsD}^{\prime}\left( \tau_{D} \right)}{\mathbb{d}\tau_{D}}}}} \end{bmatrix} \end{matrix} & \left( {A\text{-}45} \right) \end{matrix}$

The before-closure storage coefficient is by definition always greater than the propagating-fracture storage coefficient, and the difference of the two coefficients cannot be zero unless the fracture half-length is created instantaneously. However, the difference is also relatively small when compared to C_(bcD) or C_(acD), and when the dimensionless time of injection is short and t_(LfD)>(t_(e))_(LfD), the integral term containing the propagating-fracture storage coefficient becomes negligibly small.

Thus, with a short dimensionless time of injection and (t_(e))_(LfD)□t_(LfD)<(t_(c))_(LfD′) the limiting-case before-closure dimensionless wellbore pressure solution may be written as $\begin{matrix} \begin{matrix} {{p_{wsD}\left( t_{LfD} \right)} = {{{p_{wsD}(0)}C_{acD}{p_{acD}^{\prime}\left( t_{LfD} \right)}} -}} \\ {\left( {C_{bcD} - C_{acD}} \right){\int_{0}^{t_{LfD}}{{p_{acD}^{\prime}\left( {t_{LfD} - \tau_{D}} \right)}{p_{wsD}^{\prime}\left( \tau_{D} \right)}{\mathbb{d}\tau_{D}}}}} \end{matrix} & \left( {A\text{-}46} \right) \end{matrix}$ which may be simplified in the Laplace domain and inverted back to the time domain to obtain the before-closure limiting-case dimensionless wellbore pressure solution written as p _(wsD)(t _(LfD))=p _(wsD)(0)C _(bCD) p′ _(bCD)(t _(LfD))   (A-47) which is the slug test solution for a hydraulically fractured well with constant before-closure storage.

When the dimensionless time of injection is short and t_(LfD)□(t_(c))_(LfD)□(t_(e))_(LfD), the fracture solution derivative may be approximated as p′ _(fD)(t_(LfD)−τ_(D))≡p′ _(fD)(t_(LfD)),   (A-48) and with t_(LfD)□(t_(c))_(LfD) and p′ _(acD)(t_(LfD)−τ_(D))≡p′_(acD)(t_(LfD)), the dimensionless wellbore pressure solution may written as p _(wsD)(t _(LfD))=[p _(wsD)(0)C _(bCD) −p _(wsD)((t _(c))_(LfD))(C _(bCD) −C _(acD))]p′ _(acD)(t _(LfD))   (A-49) which is a variable storage slug-test solution. IV. Nomenclature

The nomenclature, as used herein, refers to the following terms:

-   A=fracture area during propagation, L², m² -   A_(f)=fracture area, L², m² -   A_(ij)=matrix element, dimensionless -   B=formation volume factor, dimensionless -   c_(f)=compressibility of fluid in fracture, Lt²/m, Pa⁻¹ -   c_(t)=total compressibility, Lt²/m, Pa⁻¹ -   C_(wb)=compressibility of fluid in wellbore, Lt²/m, Pa⁻¹ -   C=wellbore storage, L⁴t²/m, m³/Pa -   C_(f)=fracture conductivity, m³, m³ -   C_(ac)=after-closure storage, L⁴t²/m, m³/Pa -   C_(bc)=before-closure storage, L⁴t²/m, m³/Pa -   C_(pf)=propagating-fracture storage, L⁴t²/m, m³/Pa -   C_(fbc)=before-closure fracture storage, L⁴t²/m, m³/Pa -   C_(pLf)=propagating-fracture storage with multiple fractures,     L⁴t²/m, m³/Pa -   C_(Lfac)=after-closure multiple fracture storage, L⁴t²/m, m³/Pa -   C_(Lfbc)=before-closure multiple fracture storage, L⁴t²/m, m³/Pa -   h=height, L, m -   h_(f)=fracture height, L, m -   I=integral, m/Lt, Pa·s -   k=permeability, L², m² -   k_(x)=permeability in x-direction, L², m² -   k_(y)=permeability in y-direction, L², m² -   K₀=modified Bessel function of the second kind (order zero),     dimensionless -   L=propagating fracture half length, L, m -   L_(f)=fracture half length, L, m -   n_(f)=number of fractures, dimensionless -   n_(fs)=number of fracture segments, dimensionless -   p₀=wellbore pressure at time zero, m/Lt², Pa -   p_(c)=fracture closure pressure, m/Lt², Pa -   p_(f)=reservoir pressure with production from a single fracture,     m/Lt², Pa -   p_(i)=average reservoir pressure, m/Lt², Pa -   p_(n)=fracture net pressure, m/Lt², Pa -   p_(w)=wellbore pressure, m/Lt², Pa -   p_(ac)=reservoir pressure with constant after-closure storage,     m/Lt², Pa -   p_(Lf)=reservoir pressure with production from multiple fractures,     m/Lt², Pa -   p_(pf)=reservoir pressure with a propagating fracture, m/Lt², Pa -   p_(wc)=wellbore pressure with constant flow rate, m/Lt², Pa -   p_(ws)=wellbore pressure with variable flow rate, m/Lt², Pa -   P_(fac)=fracture pressure with constant after-closure fracture     storage, m/Lt², Pa -   p_(pLf)=reservoir pressure with a propagating secondary fracture,     m/Lt², Pa -   p_(Lfac)=reservoir pressure with production from multiple fractures     and constant after-closure storage, m/Lt², Pa -   p_(Lfbc)=reservoir pressure with production from multiple fractures     and constant before-closure storage, m/Lt², Pa -   q=reservoir flow rate, L³/t, m³/s -   {tilde over (q)}=fracture-face flux, L³/t, m³/s -   q_(w)=wellbore flow rate, L³/t, m³/s -   q_(l)=fluid leakoff rate, L³/t, m³/s -   q_(s)=reservoir flow rate, L³/t, m³/s -   q_(t)=total flow rate, L³/t, m³/s -   q_(f)=fracture flow rate, L³/t, m³/s -   q_(pf)=propagating-fracture flow rate, L³/t, m³/s -   q_(sf)=sand-face flow rate, L³/t, m³/s -   q_(ws)=wellbore variable flow rate, L³/t, m³/s -   r=radius, L, m -   s=Laplace transform variable, dimensionless -   S_(e)=Laplace transform variable at the end of injection,     dimensionless -   S_(f)=fracture stiffness, m/L²t², Pa/m -   S_(fs)=fracture-face skin, dimensionless -   (S_(fs))_(ch)=choked-fracture skin, dimensionless -   t=time, t, s -   t_(e)=time at the end of an injection, t, s -   t_(c)=time at hydraulic fracture closure, t, s -   t_(LfD)=dimensionless time, dimensionless -   u=variable of substitution, dimensionless -   U_(a)=Unit-step function, dimensionless -   V_(f)=fracture volume, L³, m³ -   V_(fr)=residual fracture volume, L³, m³ -   V_(w)=wellbore volume, L³, m³ -   ŵ_(f)=average fracture width, L, m -   x=coordinate of point along x-axis, L, m -   x=coordinate of point along x-axis,, L, m -   {tilde over (x)}_(w)=wellbore position along {tilde over (x)}-axis,     L, m -   y=coordinate of point along y-axis, L, m -   {tilde over (y)}=coordinate of point along {tilde over (y)}-axis, L,     m -   y_(w)=wellbore position along y-axis, L, m -   α=fracture growth exponent, dimensionless -   δ_(L)=ratio of secondary to primary fracture half length,     dimensionless -   Δ=difference, dimensionless -   ζ=variable of substitution, dimensionless -   η=variable of substitution, dimensionless -   θ_(r)=reference angle, radians -   θ_(f)=fracture angle, radians -   μ=viscosity, m/Lt, Pa·s -   ξ=variable of substitution, dimensionless -   ρ=density, m/L³, kg/m³ -   τ=variable of substitution, dimensionless -   φ=porosity, dimensionless -   χ=variable of substitution, dimensionless -   ψ=variable of substitution, dimensionless     Subscripts -   D=dimensionless -   i=fracture index, dimensionless -   j=segment index, dimensionless -   l=fracture index, dimensionless -   m=segment index, dimensionless -   n=time index, dimensionless

To facilitate a better understanding of the present invention, the following example of certain aspects of some embodiments are given. In no way should the following examples be read to limit, or define, the scope of the invention.

EXAMPLES Field Example

A fracture-injection/falloff test in a layer without a pre-existing fracture is shown in FIG. 6, which contains a graph of injection rate and bottomhole pressure versus time. A 5.3 minute injection consisted of 17.7 bbl of 2% KCl treated water followed by a 16 hour shut-in period. FIG. 7 contains a graph of equivalent constant-rate pressure and pressure derivative—plotted in terms of adjusted pseudovariables using methods such as those disclosed in Craig, D. P., Analytical Modeling of a Fracture-Injection/Falloff Sequence and the Development of a Refracture-Candidate Diagnostic Test, PhD dissertation, Texas A&M Univ., College Station, Tex. (2005)—overlaying a constant-rate drawdown type curve for a well producing from an infinite-conductivity vertical fracture with constant storage. Fracture half length is estimated to be 127 ft using Nolte-Shlyapobersky analysis as disclosed in Valkó, P. P. and Economides, M. J., Fluid-Leakoff Delineation in High Permeability Fracturing, SPE PRODUCTION AND FACILITIES (MAY 1986), and the permeability from a type curve match is 0.827 md, which agrees reasonably well with a permeability of 0.522 md estimated from a subsequent pressure buildup test type-curve match.

Thus, the above results show, among other things:

-   -   An isolated-layer refracture-candidate diagnostic test may         require a small volume, low-rate injection of liquid or gas at a         pressure exceeding the fracture initiation and propagation         pressure followed by an extended shut-in period.     -   Provided the injection time is short relative to the reservoir         response, a fracture-injection/falloff sequence may be analyzed         as a slug test.     -   Quantitative type-curve analysis using constant-rate drawdown         solutions for a reservoir producing from infinite or finite         conductivity fractures may be used to estimate reservoir         transmissibility of a formation.

Therefore, the present invention is well adapted to attain the ends and advantages mentioned as well as those that are inherent therein. While numerous changes may be made by those skilled in the art, such changes are encompassed within the spirit of this invention as defined by the appended claims. The terms in the claims have their plain, ordinary meaning unless otherwise explicitly and clearly defined by the patentee. 

1. A method of determining a reservoir transmissibility of at least one layer of a subterranean formation having a reservoir fluid comprising the steps of: (a) isolating the at least one layer of the subterranean formation to be tested; (b) introducing an injection fluid into the at least one layer of the subterranean formation at an injection pressure exceeding the subterranean formation fracture pressure for an injection period; (c) shutting in the wellbore for a shut-in period; (d) measuring pressure falloff data from the subterranean formation during the injection period and during a subsequent shut-in period; and (e) determining quantitatively the reservoir transmissibility of the at least one layer of the subterranean formation by analyzing the pressure falloff data with a fracture-injection/falloff test model.
 2. The method of claim 1 wherein step (e) is accomplished by transforming the pressure falloff data to equivalent constant-rate pressures and using type curve analysis to match the equivalent constant-rate pressures to a type curve to determine quantitatively the reservoir transmissibility.
 3. The method of claim 1 wherein step (e) is accomplished by: transforming the pressure falloff data to obtain equivalent constant-rate pressures; preparing a log-log graph of the equivalent constant-rate pressures versus time; and determine quantitatively the reservoir transmissibility of the at least one layer of the subterranean formation by analyzing the variable-rate pressure falloff data using type-curve analysis according to a fracture-injection/falloff test model.
 4. The method of claim 2 wherein the reservoir fluid is compressible; and wherein the transforming of the pressure falloff data is based on the properties of the compressible reservoir fluid contained in the reservoir wherein the transforming step comprises: determining a shut-in time relative to the end of the injection period; determining an adjusted time; and determining an adjusted pseudopressure difference.
 5. The method of claim 4 wherein the transforming step comprises: determining a shut-in time relative to the end of the injection period: Δt=t−t_(ne); determining an adjusted time: ${t_{a} = {\left( {\overset{\_}{\mu}{\overset{\_}{c}}_{t}} \right){\int_{0}^{\Delta\quad t}\frac{{\mathbb{d}\Delta}\quad t}{\left( {\mu c}_{t} \right)_{w}}}}};$ and determining an adjusted pseudopressure difference: Δp_(a)(t)=p_(aw)(t)−p_(ai) where ${p_{a} = {\frac{{\overset{\_}{\mu}}_{g}\overset{\_}{z}}{\overset{\_}{p}}{\int_{0}^{p}\frac{p{\mathbb{d}p}}{\mu_{g}z}}}};$ wherein: t_(ne) is the time at the end of the injection period; μ is the viscosity of the reservoir fluid at average reservoir pressure; (μc_(t))_(w) is the viscosity compressibility product of wellbore fluid at time t; (μc_(t))₀ is the viscosity compressibility product of wellbore fluid at time t=t_(ne); p is the pressure; p is the average reservoir pressure; p_(aw)(t) is the adjusted pressure at time t; p_(ai) is the adjusted pressure at time t=t_(ne); c_(t) is the total compressibility; c _(t) is the total compressibility at average reservoir pressure; and z is the real gas deviator factor.
 6. The method of claim 5 further comprising the step of preparing a log-log graph of a pressure function versus time: I(Δp_(a))=f(t_(a)); where I(Δ  p_(a)) = ∫₀^(t_(a))Δ  p_(a)𝕕t_(a).
 7. The method of claim 5 further comprising the step of preparing a log-log graph of a pressure derivative function versus time: Δp_(a)′=f(t_(a)); where ${\Delta\quad p_{a}^{\prime}} = {\frac{\mathbb{d}\left( {\Delta\quad p_{a}} \right)}{\mathbb{d}\left( {\ln\quad t_{a}} \right)} = {\Delta\quad p_{a}{t_{a}.}}}$
 8. The method of claim 2 wherein the reservoir fluid is slightly compressible and the transforming of the variable-rate pressure falloff data is based on the properties of the slightly compressible reservoir fluid contained in the reservoir wherein the transforming step comprises: determining a shut-in time relative to the end of the injection period; and determining a pressure difference.
 9. The method of claim 8 the transforming step comprises: determining a shut-in time relative to the end of the injection period: Δt=t−t_(ne); and determining a pressure difference: Δp(t)=p_(w)(t)−p_(i); wherein: t_(ne) is the time at the end of injection period; p_(w)(t) is the pressure at time t; and p_(i) is the initial pressure at time t=t_(ne).
 10. The method of claim 9 further comprising the step of preparing a log-log graph of a pressure function versus time: I(Δp)=f(Δt).
 11. The method of claim 10 where I(Δ  p) = ∫₀^(Δ  t)Δ  p𝕕Δ  t  or  ∫₀^(t)Δ  p𝕕t.
 12. The method of claim 9 further comprising the step of preparing a log-log graph of a pressure derivatives function versus time: Δp′=f(Δt).
 13. The method of claim 12 where ${\Delta\quad p^{\prime}} = {\frac{\mathbb{d}\left( {\Delta\quad p} \right)}{\mathbb{d}\left( {\ln\quad\Delta\quad t} \right)} = {{\Delta\quad p\quad\Delta\quad t\quad{or}\quad\frac{\mathbb{d}\left( {\Delta\quad p} \right)}{\mathbb{d}\left( {\ln\quad t} \right)}} = {\Delta\quad p\quad{t.}}}}$
 14. The method of claim 9 wherein the reservoir transmissibility is determined quantitatively in field units from a before-closure match point as: $\frac{k\quad h}{\mu} = {141.2(24){p_{wsD}(0)}{{{C_{bc}\left( {p_{0} - p_{i}} \right)}\left\lbrack \frac{p_{bcD}\left( t_{D} \right)}{\int_{0}^{\Delta\quad t}{\left\lbrack {{p_{w}(\tau)} - p_{i}} \right\rbrack{\mathbb{d}\tau}}} \right\rbrack}_{M}.}}$
 15. The method of claim 9 wherein the reservoir transmissibility is determined quantitatively in field units from an after-closure match point as: $\frac{kh}{\mu} = {141.2(24){p_{awsD}(0)}{{{C_{bc}\left( {p_{a\quad 0} - p_{ai}} \right)}\left\lbrack \frac{p_{bcD}\left( t_{D} \right)}{\int_{0}^{\Delta\quad t_{a}}{\left\lbrack {{p_{aw}(\tau)} - p_{ai}} \right\rbrack{\mathbb{d}\tau}}} \right\rbrack}_{M}.}}$
 16. The method of claim 5 wherein the reservoir transmissibility is determined quantitatively in field units from a before-closure match point as: $\frac{kh}{\mu} = {141.2(24){p_{wsD}(0)}{{{C_{bc}\left( {p_{0} - p_{i}} \right)}\left\lbrack \frac{p_{bcD}\left( t_{D} \right)}{\int_{0}^{\Delta\quad t}{\left\lbrack {{p_{w}(\tau)} - p_{i}} \right\rbrack{\mathbb{d}\tau}}} \right\rbrack}_{M}.}}$
 17. The method of claim 5 wherein the reservoir transmissibility is determined quantitatively in field units from an after-closure match point as: $\frac{kh}{\mu} = {141.2(24){p_{awsD}(0)}{{{C_{bc}\left( {p_{a\quad 0} - p_{ai}} \right)}\left\lbrack \frac{p_{bcD}\left( t_{D} \right)}{\int_{0}^{\Delta\quad t_{a}}{\left\lbrack {{p_{aw}(\tau)} - p_{ai}} \right\rbrack{\mathbb{d}\tau}}} \right\rbrack}_{M}.}}$
 18. A system for determining a reservoir transmissibility of at least one layer of a subterranean formation by using variable-rate pressure falloff data from the at least one layer of the subterranean formation measured during an injection period and during a subsequent shut-in period, the system comprising: a plurality of pressure sensors for measuring pressure falloff data; and a processor operable to transform the pressure falloff data to obtain equivalent constant-rate pressures and to determine quantitatively the reservoir transmissibility of the at least one layer of the subterranean formation by analyzing the variable-rate pressure falloff data using type-curve analysis according to a fracture-injection/falloff test model.
 19. A computer program, stored on a tangible storage medium, for analyzing at least one downhole property, the program comprising executable instructions that cause a computer to: determine quantitatively a reservoir transmissibility of the at least one layer of the subterranean formation by analyzing the variable-rate pressure falloff data with a fracture-injection/falloff test model.
 20. The computer program of claim 19 wherein the determining step is accomplished by transforming the variable-rate pressure falloff data to equivalent constant-rate pressures and using type curve analysis to match the equivalent constant-rate rate pressures to a type curve to determine the reservoir transmissibility.
 21. The computer program of claim 19 wherein the determining step is accomplished by transforming the variable-rate pressure falloff data to equivalent constant-rate pressures and using after closure analysis to determine the reservoir transmissibility. 